DE10140356A1 - Tubular discharge lamp with ignition aid - Google Patents

Abstract

A dielectric barrier discharge lamp (1) comprises a tubular discharge chamber (2), a fluorescent layer on at least one part of the inner wall of the discharge chamber (2) and longitudinal electrodes (3). A coating (10) is provided on a partial region of the inner wall at least at one end of the tubular discharge chamber (2), which, in addition, covers one end of at least one longitudinal electrode (3). The material of said coating (10) has a high secondary electron emission coefficient. The ignition behavior of the lamp is thus improved, especially on ignition in darkness.

Description

Technical field

The invention relates to a dielectric barrier discharge lamp a tubular discharge vessel and a phosphor layer.

Dielectric barrier discharge lamps are sources of electromagnetic Radiation based on dielectric barrier gas discharges.

The discharge vessel is usually filled with an inert gas, for example xenon, or a gas mixture. So-called excimers are formed during the gas discharge, which is preferably operated by means of a pulsed operating method described in US Pat. No. 5,714,835. Excimers are excited molecules, e.g. B. Xe _{2 *} , which emit electromagnetic radiation when returning to the generally unbound basic state. In the case of Xe _{2 *} , the maximum of the molecular band radiation is approximately 172 nm (VUV radiation). The phosphor layer is used to convert the invisible VUV radiation into visible (VIS) radiation (light).

Such lamps are used particularly in devices for office automation (OA = Office Automation), e.g. B. color copiers and scanners for Signal lighting, e.g. B. as a brake and direction indicator light in automobiles for Auxiliary lighting, e.g. B. the interior lighting of automobiles, as well as for the Backlighting ads, e.g. B. liquid crystal displays as so-called "Edge Type Backlights" are used.

In these technical fields of application, both are particularly short Start-up phases, but also temperature-independent luminous fluxes required. That is why these lamps do not contain mercury.

Both high luminance and uniform luminance over the length of the lamp are necessary for the applications mentioned. For OA use, the inner wall of the discharge vessel is usually provided with a VUV / VIS reflection layer, for example Al ₂ O ₃ and / or TiO ₂ . In this case, an aperture extending along the longitudinal axis of the lamp remains free of reflection layers, since the VUV / VIS reflection layer is also impermeable to the light emitted by the phosphor layer. The actual phosphor layer is located on the VUV / VIS reflection layer, and the aperture can optionally also be coated with phosphor or free of phosphor. In any case, the desired high luminance can be generated due to the VUV / VIS reflection layer within the aperture without the reflection layer.

A dielectric barrier discharge lamp necessarily sets at least one so-called dielectric barrier electrode in advance. A dielectric barrier electrode is opposite the inside of the Discharge vessel separated by means of a dielectric barrier. This dielectric barrier can, for example, as a dielectric layer covering the electrode be carried out, or it is through the discharge vessel of the lamp itself formed, namely when the electrode on the outer wall of the discharge vessel is arranged.

Due to the dielectric barrier is necessary for the operation of such lamps a time-varying voltage between the electrodes is required, for example a sinusoidal AC voltage or a pulse voltage as disclosed in the aforementioned U.S. Patent No. 5,714,835.

State of the art

In US-A 6 097155 a dielectric barrier discharge lamp is the disclosed type. The lamp has a tubular Discharge vessel on the inside and / or outside wall of at least two elongated, conductor-like electrodes parallel to the longitudinal axis of the Discharge vessel are arranged oriented. However, the long is a disadvantage Ignition delay after applying voltage to the electrodes of the Lamp when the lamp is in the dark, for example within an OA device. After a long time in the dark, it can even occur that the lamp is only with the Ignite normal operation of significantly increased voltage.

DE-A 42 03 594 discloses a lamp with a discharge tube which has a transparent tube filled with a discharge gas and two electrodes which generate a spatial discharge in the tube, the two electrodes running essentially parallel to the length of the tube and one electrode is arranged centrally axially inside the tube and the other outside the tube. In addition, the surface of the inner electrode and / or the inner side of the tube is coated with a coating material made of a metal with a high secondary emission ratio and / or a dielectric. Rare earth oxides, aluminum oxide (Al ₂ O ₃ ), silicon oxide (SiO ₂ ) or magnesium oxide (MgO) is used as the coating material. The more preferred coating material is magnesium oxide, which can also act as a protective layer. Disadvantages of this lamp are, on the one hand, shadowing by the rod-shaped inner electrode, and on the other hand the small proportion of the phosphor layer based on the total area of the inner wall of the discharge vessel, which inevitably leads to a loss in the luminous flux of the lamp based on the maximum possible luminous flux. In DE-A 42 03 594 it is namely provided that the upper half of the inner wall of the vessel is coated with a phosphor and the lower half is coated with a layer with a high secondary electron emission coefficient (combination of the two FIGS. 4A and 4B).

Presentation of the invention

The object of the present invention is to provide a dielectric barrier Discharge lamp with a tubular discharge vessel and one To provide a phosphor layer according to the preamble of claim 1, which has an improved ignition behavior.

This task is performed on a lamp with the features of the generic term of claim 1 by the features of the characterizing part of Claim 1 solved. Particularly advantageous configurations can be found in the dependent claims.

The dielectric barrier discharge lamp according to the invention has a tubular discharge vessel and a phosphor layer on at least a part of the inner wall of the discharge vessel. Also are elongated dielectric oriented parallel to the longitudinal axis of the discharge vessel disabled electrodes arranged on the vessel wall. At least one end of the tubular discharge vessel is on a portion of the Provide the inside wall with a coating that also has at least one end an elongated electrode covered, the material of this coating has a high secondary electron emission coefficient (short referred to below as SEE coating). The sea- The coating is in direct contact with that of the discharge vessel included filling gas. That is why the SEE coating is always the last of possibly several functional layers on the inner wall the discharge vessel, d. H. every additional layer, for example fluorescent and / or VUV / VIS reflective layer is between SEE coating and the inner wall of the discharge vessel. That way ensures that the SEE coating is in the electrical field of the Electrons hit accelerated free electrons and thereby Secondary electrons are triggered.

The advantage of this solution is that a large part of that on the inside wall of the Discharge vessel also applied uncoated phosphor layer, d. H. is actually also effective since the SEE coating on one or both Ends of the tubular discharge vessel is limited. It also bothers a slight shade at the lamp ends less than in the Lamp center. That is why the SEE coating is also on the area at the end limited at least one elongated electrode. But it does play doesn't matter if the coating extends beyond the electrode end extends to the corresponding end of the vessel, since in this area anyway no more discharge burns and consequently this area is dark. This dark area is therefore preferred with respect to the total length of the Lamp kept as small as possible. The one with the coating Part of the inner wall is preferably less than 25%, better less than 10% of the total area of the inner wall along the longitudinal axis of the tubular discharge vessel, d. H. the lateral surface.

In one embodiment, the SEE coating preferably overlaps End of the elongated electrode, the overlap in the range of greater than 0 and less than or equal to 10 mm, preferably in the range of greater than 2 and is less than or equal to 6 mm. Since it is due to the transverse Discharge configuration is possible to operate lamps of different lengths, be this Point out the relative overlap that typically occurs in Range greater than 0 and less than or equal to 20%, preferably in the range of greater than 0 and less than or equal to 10% of the total length of the lamp.

With electrodes arranged on the inner wall of the discharge vessel (Inner wall electrodes), as disclosed in the already mentioned US-A 6 097 155, The overlap initially relates to that of the power supply opposite end of the electrode. However, the SEE coating can of course also the power supply end of the electrode cover. At this point it should only be briefly pointed out that the Inner wall electrode, the electrical feedthrough and the power supply preferably as functionally different areas of a single one conductor-like means are realized. The means similar to a conductor track itself no structural separation in the electrode, power supply, etc. The individual areas are rather defined by their function. The electrode is consequently the area of the conductor-like means which is located within of the discharge vessel. For further details, please refer to the US-A 6 097 155 and the exemplary embodiments referenced. So that's the term "Overlap" at the power supply end of one To interpret the inner wall electrode as a cover.

Another advantage is that the lamp according to the invention is relatively easy to manufacture. Suitable materials for the SEE coating are those which have a secondary electron emission coefficient greater than one, in particular greater than two, preferably greater than 3, particularly preferably in the range between 3 and 15. Powdery Al ₂ O ₃ or MgO in paste-like preparation is particularly suitable. The relevant end of the lamp is then simply immersed in the paste until the desired overlap with the corresponding electrode end is achieved. In this case, the SEE coating has the outer shape of a ring. The outer wall of the discharge vessel is advantageously covered during immersion.

In principle, however, it is sufficient to improve the ignition behavior if the SEE coating is limited to a relatively small part of a ring is as long as the end of at least one electrode is covered with it. This leaves for example by pasting with a suitable tool, e.g. B. a brush, possibly with the help of an appropriate mask accomplish. A thin-walled hollow cylinder or longitudinal part is suitable as a mask a hollow cylinder, the outer diameter of which approximately Corresponds to the inside diameter of the discharge vessel. The wall of the hollow cylinder faces an opening whose shape is that of the coating to be applied equivalent. The hollow cylinder becomes tubular at the end Discharge vessel inserted until the opening is above the electrode end and then paste the paste inside the opening onto the inside wall of the Discharge vessel or the electrode end applied. After drying and the mask can be removed if the paste is still heated.

In addition, it is generally sufficient if at least one end is only one single electrode has a SEE coating. If the lamp for the Operation with unipolar voltage pulses, the SEE- Coating can be arranged on the anode. Only then can Primary electrons accelerated towards the SEE coating and at Impact there secondary electrons for the further development of the Ignition process are triggered. For lamps for operation with bipolar This distinction is irrelevant to voltage pulses since the electrodes in pairs their roles (current anode or cathode) depending on the polarity of the change the current voltage pulse.

It is also advantageous for bipolar operation to have the ends of both To provide electrodes of a pair of electrodes with a SEE coating. Then This ensures that with every voltage pulse, regardless of whose polarity, the current anode in any case with a SEE Coating is provided and thus a secondary electron emission can take place. This variant also increases the Probability for a quick and reliable ignition.

Usually, but not necessarily, the invention Discharge lamp on one or both ends on a base. Then the SEE coating on the inside of the base is advantageous Part of the inner wall of the discharge vessel arranged, since none additional shading occurs due to the SEE coating more.

In addition, it can be advantageous to have one at both ends of the lamp SEE coating should be provided, since the ignition is ideally from both Ends out. In any case, this variant increases the Probability for a quick and reliable ignition. It is under It may be sufficient if both coating zones are narrower than with coating on only one end. It can also be used for variant coated on both sides may also be advantageous in the coating zone Socket area wider than in the opposite socket-free end interpreted. This variant combines the advantages of a stronger ignition in the wide coating zone in the base area with little shading the narrower coating zone at the base-free end of the lamp.

Description of the drawings

In the following, the invention will be explained in more detail using two exemplary embodiments are explained. Show it:

FIG. 1a is a plan view of a first embodiment,

FIG. 1b a cross section of the embodiment of FIG. 1a taken along the line DD,

Fig. 2 shows a second embodiment.

FIGS. 1a and 1b schematically show a rod-shaped fluorescent lamp 1 in the plan view and taken along the line DD in cross section. The lamp 1 consists essentially of a tubular discharge vessel 2 made of soda-lime glass with a circular cross-section and two strip-shaped electrodes 3 (the second electrode is covered and therefore cannot be seen) made of silver solder, which is arranged parallel to the longitudinal axis of the tube and diametrically arranged to one another on the inside of the wall of the Discharge vessel 2 are applied. Each of the inner wall electrodes 3 is covered with a dielectric barrier 4 made of glass solder. Furthermore, the inside of the wall of the discharge vessel is covered with a phosphor layer 5 and, with the exception of an aperture extending along the longitudinal axis of the lamp, with the VUV / VIS reflection layer 6 made of Al ₂ O ₃ below the phosphor layer 5 (for illustrative reasons only in FIG shown. 1b).

A first end of the discharge vessel 2 is closed by means of a blunt fusion 7 . The two electrodes 3 end at a distance A = 5 mm before this fusion 5 . The electrodes 3 are guided gas-tight to the outside through the other end of the discharge vessel 2 and pass into an external power supply 8 there in each case. The second end of the discharge vessel 2 is closed by means of a plate-shaped closure element (not visible in this illustration). For this purpose, the edge of the plate-shaped closure element is fused with a constriction 9 of the discharge vessel 2 . For further details, reference is made to German patent application No. 100 48 410.7, the disclosure content of which is hereby incorporated by reference. By means of the aforementioned technology, the inner wall electrode 3 , the electrical feedthrough in the area of the constriction 9 and the power supply 8 are realized as functionally different areas of a single silver solder strip similar to a conductor track.

At the first end of the discharge vessel 2 , an annular coating 10 of width B = 10 mm — viewed in the direction of the longitudinal axis of the discharge vessel 2 — made of MgO (porous magnesium oxide) is applied to the inner wall, more precisely directly on the phosphor layer 5 . The ring-shaped MgO coating 10 closes on the one hand directly with the end 5 of the discharge vessel 2 and was produced by immersing this end of the vessel in an MgO paste. On the other hand, the width B of the ring-shaped MgO coating 10 was chosen such that the ring covers the end of the electrodes 3 by the overlap C = 5 mm (= B minus A). This ensures that the MgO ring 10, as a secondary electron emitter, improves the ignition properties of the lamp 1 . At the same time, shading by the MgO ring 10 is limited to an annular partial area with a width B of only 5 mm. This is only approx. 1.5% based on the total lighting length of the lamp 1 of 350 mm (measured from the constriction 9 to the end of the electrodes 3 ).

FIG. 2 shows a schematic top view of a variant of the embodiment of FIGS. 1a, 1b (same features are provided with the same reference numerals), in which an MgO coating in the form of two short 5 mm wide partial rings 11 on the plate seal or Constriction 9 directly adjacent ends of both electrodes 3 are applied. More precisely, each of the two partial rings 11 (one of the two partial rings 11 is covered for the sake of illustration) is applied to the phosphor covering the electrodes 3 and the dielectric 4 . In addition, this end of the lamp 1 is provided with a base, not shown, which covers the two MgO part rings 11 .

Claims (13)

1. Dielectric barrier discharge lamp ( 1 ) with a tubular discharge vessel ( 2 ) and a phosphor layer ( 5 ) on at least part of the inner wall of the discharge vessel ( 2 ) and with dielectrically impeded, elongated electrodes ( 3 ) which are parallel to the longitudinal axis of the discharge vessel ( 2 ) are arranged oriented on the vessel wall, characterized in that at least one end of the tubular discharge vessel ( 2 ) is provided on a partial area of the inner wall with a coating ( 10 ; 11 ) which also has an end of at least one elongate electrode ( 3 ) covered, the material of this coating ( 10 ; 11 ) having a high secondary electron emission coefficient. 2. Discharge lamp according to claim 1, wherein the portion of the inner wall provided with the coating ( 10 ; 11 ) is less than 25%, better less than 10% of the total area of the inner wall along the longitudinal axis of the discharge vessel ( 2 ). 3. Discharge lamp according to claim 1 or 2, wherein the coating has the outer shape of a ring ( 10 ) or at least a part ( 11 ) of a ring. 4. Discharge lamp according to one of claims 1, 2 or 3, wherein the coating ( 10 ; 11 ) overlaps one end of at least one elongated electrode ( 3 ). 5. Discharge lamp according to claim 4, wherein the overlap (D) in Range greater than 0 and less than or equal to 10 mm, preferably in the range of greater than 2 and less than or equal to 6 mm. 6. Discharge lamp according to claim 4, wherein the overlap (D) in Range greater than 0 and less than or equal to 20%, preferably in the range of is greater than 0 and less than or equal to 10%. 7. discharge lamp according to one of the preceding claims with base, the coating on the part lying inside the base the inner wall of the discharge vessel is arranged. 8. Discharge lamp according to one of the preceding claims, wherein the Lamp on both ends a coating of material with a has high secondary electron emission coefficient. 9. Discharge lamp according to claim 8 with a base at one end of the discharge vessel, the coating zone at the base end in Direction of the longitudinal axis of the tubular discharge vessel wider is as at the base distant end of the lamp. 10. Discharge lamp according to one of the preceding claims, wherein the material of the coating ( 10 ; 11 ) has a secondary electron emission coefficient greater than one, in particular greater than two, preferably greater than 3, particularly preferably in the range between 3 and 15. 11. Discharge lamp according to one of the preceding claims, wherein the coating material ( 10 ; 11 ) comprises powder-like Al ₂ O ₃ or MgO. 12. Discharge lamp according to one of the preceding claims, wherein at least one of the electrodes ( 3 ) is arranged on the inner wall of the discharge vessel ( 2 ). 13. Discharge lamp according to one of the preceding claims, a VUV / VIS reflection layer ( 6 ) being arranged between the inner wall of the discharge vessel ( 2 ) and the phosphor layer ( 5 ), an aperture extending along the longitudinal axis of the lamp being free of reflection layers.